Bioscience Journal  |  2021  |  vol. 37, e37056  |  ISSN 1981-3163 
 

1 

 

 
 

Ana Ligia GIRALDELI1,2 , André Felipe Moreira SILVA3 , Luisa Carolina BACCIN2 ,  

Lucas da Silva ARAÚJO2 , Gustavo Soares da SILVA2 ,  

Ana Carolina Viviani PAGENOTTO4 , Ricardo VICTORIA FILHO5  
 
1 Department of Agronomy, State University of Londrina, Londrina, Paraná, Brazil. 
2 Postgraduate Program in Crop Science, University of São Paulo, Luiz de Queiroz College of Agriculture, Piracicaba, São Paulo, Brazil. 
3 Crop Science Pesquisa e Consultoria Agronômica, Palotina, Paraná, Brazil. 
4 Graduation in Agronomic Engineering, University of São Paulo, Luiz de Queiroz College of Agriculture, Piracicaba, São Paulo, Brazil. 
5 Department of Crop Science, University of São Paulo, Luiz de Queiroz College of Agriculture, Piracicaba, São Paulo, Brazil.  

 
Corresponding author: 
Ana Ligia Giraldeli 
Email: analigia_giraldeli@hotmail.com 
 
How to cite: GIRALDELI, A.L., et al. Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system. Bioscience 
Journal. 2021, 37, e37056. https://doi.org/10.14393/BJ-v37n0a2021-51527 

 
Abstract 
Among the main weeds with difficult to control in the sugarcane fields can be cited purple nutsedge (Cyperus 
rotundus L.). This specie was observed in the seed bank in sugarcane fields harvested with or without 
burning. The objective of this study was to evaluate the efficacy of herbicides in pre-sprouted seedlings (PSS) 
of sugarcane in the control of C. rotundus and other weeds. The work was carried out in the field, in a 
randomized complete block design, and four replications. The treatments corresponded to the herbicides 
applied in pre-planting: sulfentrazone (800 g a.i. ha-1), diclosulam (193.17 g a.i. ha-1), imazapic (133 g a.i. ha-
1) and imazapyr (500 g a.e. ha-1); post-planting: halosulfuron (112.5 g a.i. ha-1), ethoxysulfuron (135 g a.i. ha-
1), MSMA (1,975 g a.i. ha-1) and 2,4-D (1,340 g a.e. ha-1); besides a control treatment weeding and another 
without weeding. The symptoms of injury on sugarcane plants, percentage of weed control, variables related 
to agronomic performance of sugarcane, and yield were evaluated. The herbicides diclosulam, imazapic, and 
imazapyr caused serious damage to the crop. The halosulfuron, ethoxysulfuron, MSMA, and 2,4-D did not 
cause symptoms of injury to sugarcane, however, the treatments had a reduced yield due to the low weed 
control. The sulfentrazone treatment obtained the second highest yield but with effective weed control 
(>70%) up to 45 days after planting. The best controls were obtained with pre-planting treatments; however, 
herbicide positioning studies should be performed in relation to PSS. 
 
Keywords: Control. Herbicides. Post-planting. Pre-planting. Saccharum spp. 
 
1. Introduction 

Among the main weeds with difficult to control in the sugarcane fields can be cited purple nutsedge 
(Cyperus rotundus L.). This specie was observed in the seed bank in sugarcane fields harvested with or 
without burning (Ferreira et al. 2013), with quantities of up to 15 t ha-1 of straw (Ferreira et al. 2010), 
considered the main weed among the 15 species found, presenting high accumulated Relative Importance 
(IR%) of 1,299 in green cane (Kuva et al. 2007). Regarding the influence of Cyperus spp. on sugarcane, this 
weed can reduce until 45.2% of the yield of sugarcane (Durigan et al. 2005). Also, the level of interference 
of C. rotundus can also vary according to the sugarcane cultivar, at the pre-sprouted seedling (PSS) system 
(Giraldeli et al. 2018). Among the weeds belonging to the Cyperaceae family can be cited C. difformis L., C. 

CHEMICAL MANAGEMENT OF Cyperus rotundus L. AND 
OTHER WEEDS AT SUGARCANE IN PSS SYSTEM 

https://orcid.org/0000-0002-7452-0370
https://orcid.org/0000-0002-4846-8089
https://orcid.org/0000-0001-6456-6044
https://orcid.org/0000-0001-5720-8476
https://orcid.org/0000-0003-3267-7254
https://orcid.org/0000-0002-8761-6427
https://orcid.org/0000-0002-2185-8773


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2 

Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system 

esculentus L., C. iria L., C. odoratus L., and C. rotundus. These species have characteristics in common, such 
as triangular stem and can be annual or perennial, herbaceous, and erect. Depending on the species 
reproduction occurs via seeds as in the case of C. difformis, C. iria e C. odoratus. For C. esculentus e C. 
rotundus reproduction also occurs via tubers, being very expressive for the second species (Alves et al. 2009; 
Lorenzi 2014). 

For C. rotundus, reproduction via tubers makes it difficult to control, especially the chemical, because 
the herbicides need to translocate in the plant and reach sufficiently to the organs of vegetative propagation 
(Brecke et al. 2005). In this context, some products used in sugarcane may help control, such as diclosulam, 
imazapic, imazapyr, sulfentrazone, MSMA, 2,4-D, halosulfuron, glyphosate and ethoxysulfuron, applied at 
pre, post or late post-emergence, as recommended (Rodrigues and Almeida 2018). 

Herbicides sulfentrazone (800 g a.i. ha-1), imazapic (147 g a.i. ha-1) and halosulfuron (112,5 g a.i. ha-1) 
reduced the number and weight of viable tubers and increased the number of dead tubers of C. rotundus, 
compared to control without application, highlighting sulfentrazone (Silva et al. 2014). However, further 
studies are needed to understand the chemical management of C. rotundus in PSS. It is noteworthy that in 
areas where PSSs are planted for the purpose of multiplication for commercial areas there is no straw, which 
favors weeds of smaller and photoblastic positive seeds, such as Poaceae family species, which hinders the 
management with herbicides of broad spectrum (Silva et al. 2018). Thus, if chemical management may differ 
in the PSS system, this study aimed to evaluate the efficacy of herbicides for the control of C. rotundus and 
other weeds in pre-sprouted sugarcane seedlings. 
 
2. Material and Methods 

The experiment was carried out in an experimental area in Piracicaba, state of São Paulo, Brazil 
(22°42'47.8"S 47°37'14.6"W, altitude 547 m). The climate of the region, according to Köeppen classification 
is Cwa type, relatively dry in winter, with rain in summer. Figure 1 shows the rainfall and temperature data 
during the experiment months. 
 

 
Figure 1. Rainfall (mm), mean maximum and minimum temperature (°C) while conducting the experiment. 

Piracicaba, SP, Brazil, 2017/18. 
 

The results of the chemical analysis of the soil are presented in Table 1, being classified as medium 
texture (76.3% sand, 6.2% silt, and 17.5% clay). Before the installation of the experiment, a phytosociological 
survey of the area (November 2017) by sampling using 0.5 m side cast iron squares with an internal area of 
0.25 m2, which were launched 15 times at random. The sampled plants were counted, identified, and stored 
in properly identified paper bags and placed to dry in a forced air circulation oven at 65°C for 48 h to obtain 
the dry mass. With the sampled data we performed the descriptive analysis of weeds through 



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GIRALDELI, A.L., et al. 

phytosociological parameters represented by the IR% and IVI of the species present in the experimental area 
(Mueller-Dombois and Ellenberg 1974). These parameters will be shown in the results. 
 

Table 1. Results of soil chemical analysis of the experimental area. Piracicaba, SP, Brazil, 2017/18 

P (Resin) M.O. pH K Ca Mg Al H + Al SB CEC V m 

mg dm-3 g dm-3 CaCl2 mmolc dm-3 % 
11 17 5.5 4.6 26 9 < 2 12 36.1 48.1 75 3 

 

The experiment was installed in an area previously cultivated with soybean. Mechanical cultivation 
was carried out, fertilization with 320 kg ha-1 of 08-24-20 (N-P-K) in the planting furrow and application of 
400 g a.i. ha-1 of fipronil (Regent® 800 WG, Basf); three weeks after planting, 10.5 g a.i. ha-1 of 
chlorantraniliprole (Altacor®, WG, DuPont) was applied. The seedlings of cultivar IACSP95-5000 were planted 
on December 12, 2017, with planting lines spaced 1.5 m and 0.65 m between seedlings in the planting line. 
The plots consisted of five lines of six meters in length (36 m2), totaling 45 plants per plot (nine plants per 
line). For the evaluations, it was considered the useful area of the plots, the three central lines, excluding 
one meter at the beginning and end of the plot. After planting, the area was irrigated (approximately 20 
mm). 

The experimental design was randomized blocks with 10 treatments (Table 2) and four replications. 
PRE-planting herbicides were applied one day before sugarcane planting, the post-planting herbicides were 
applied when C. rotundus plants were in full vegetative development (4 to 5 leaves) at 30 days after planting 
(DAP). All herbicides recommended for control of C. rotundus in sugarcane were used, even knowing the 
possible damage to the crop in this application modality, as is the case of imazapyr (Rodrigues and Almeida 
2018). 
 

Table 2. Treatments used for the control of C. rotundus. Piracicaba, SP, Brazil, 2017/18. 
Treatments Commercial product Rate¹ Rate² Time³ 

1. control with weeding - - - - 
2. control without weeding - - - - 
3. sulfentrazone Boral® 500 SC 1.6 L 800 PRE 
4. diclosulam Coact® 230 g 193.17  PRE 
5. imazapic Plateau® 190 g 133 PRE 
6. imazapyr Contain® 2.0 L 500 PRE 
7. halosulfuron Sempra® 150 g 112.5  POST 
8. ethoxysulfuron Gladium® 225 g 135 POST 
9. MSMA Volcane® 2.5 L 1,975  POST 
10. 2,4-D DMA® 806 BR 2.0 L 1,340  POST 

¹ Rates of commercial products ha-1; ² Rates at g a.i. ha-1, and at g a.e. ha-1 for 2,4-D and imazapyr; ³ Herbicide application time: 
PRE-planting (one day before planting) and POST-planting (30 DAP). 

 
The spraying was carried out via CO2 pressurized sprayer, equipped with a bar with four spray nozzles, 

and flat spray fan type (XR110.02), at a constant pressure of 2.1 kgf cm-2, providing a spray volume of 200 L 
ha-1, and velocity of 1 m s-1, with the tips positioned at a height of 50 cm from the target. At the time of PRE 
applications, the environmental conditions were 26.2°C, 2.7 m s-1, and 63% relative air humidity. In POST 
applications, the environmental conditions were 25°C, 1.5 m s-1, and 86% relative air humidity. For POST 
herbicide applications, the non-ionic adhesive spreader (Agral®) was used for the halosulfuron, MSMA, and 
2,4-D, at rates of 0.5% v/v, 100 mL per 100 L of water and 0,3% v/v, respectively. 

The PSSs were evaluated for symptoms of injury through visual evaluations, in which percentages 
were assigned to each experimental unit (0 for no injuries, up to 100% for plant death), considering in this 
case symptoms significantly visible in the plants, according to their development (European Weed Research 
Council [EWRC] 1964). These evaluations were performed at 30, 45, 60, 75, and 90 DAP. Weed control was 
evaluated by visual scores ranging from 0 to 100%, where zero represents no control and 100% no weed 



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Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system 

(Velini et al. 1995). These evaluations were performed at 15, 30, 45, 60, 75, and 90 DAP, the first two only 
for pre-planting treatments. At 90 DAP, weeds were collected to determine dry mass. In these samples were 
used cast iron squares with 0.5 m side and internal area of 0.25 m2, which were randomly thrown twice in 
the useful area of the plots. The sampled plants were cut close to the ground, stored in properly identified 
paper bags, and placed to dry in a forced circulation oven at 65°C for 48 h to determine the dry mass. 

Height, diameter, and the number of tillers were evaluated at 60, 90, and 120 DAP. For this, five 
plants per plot were measured in each evaluation regarding the variables: height of the soil plant to the last 
expanded leaf, made with millimeter wooden ruler and results expressed in centimeters; stem diameter five 
cm high from the ground, made with digital calipers and results expressed in millimeters; and the number 
of tillers. At 240 DAP, plant height and diameter were also performed. Sugarcane yield was estimated for 
each treatment at 240 DAP. For this, we counted the number of stalks in six meters, and the weighing of ten 
stalks of each plot, which were cut at ground level, cleaned, and weighed on a scale to obtain the mass. The 
data obtained were extrapolated to tons of sugarcane per hectare. 

Data on injury symptoms and weed control were analyzed descriptively. For the other variables, the 
data were submitted to analysis of variance and F-test (p < 0.05), and when significant, the means were 
compared by Scott-Knott test (p < 0.05) (Pimentel-Gomes and Garcia 2002). The Sivar 5.6 program was used 
for the analysis (Ferreira 2011). 
 

3. Results 

The phytosociological survey of the area showed the presence of 12 weed species belonging to six 
families. Of these, 58.33% are monocotyledonous and 41.66% eudicotyledonous. The weeds with higher IR% 
were: C. rotundus (32.35%), Alternanthera tenella Colla (22.51%), Digitaria ciliaris (Retz.) Koeler (15,56%) 
and Portulaca oleraceae L. (7.45%). The IVI and IR% are represented in Figure 2. The weeds that occurred in 
the area and their respective families were: Amaranthaceae: Amaranthus viridis L., A. tenella; Asteraceae: 
Bidens subalternans DC., Emilia fosbergii Nicolson; Commelinaceae: Commelina benghalensis L.; 
Cyperaceae: C. rotundus; Poaceae: Cenchrus echinatus L., D. ciliaris, Eleusine indica (L.) Gaertn, Panicum 
maximum Jacq., Urochloa plantaginea (Link) R.D. Webster; Portulacaceae: P. oleraceae. 
 

 
Figure 2. Relative Importance (IR%) and Importance Value Index (IVI) of weed species present in the 

experimental area. Piracicaba, SP, Brazil, 2017/18 season. 
 

Symptoms of injury were high for pre-planting herbicides at 30 DAP. Diclosulam provided symptoms 
of 33.8%, visually characterized by chlorosis of the leaves of the crop. Already imazapic and sulfentrazone 
caused up to 37.5% of the injury, for the second herbicide reddish spots were observed in the leaf limb. 
Imazapyr was the most harmful to the crop, with 73.8% of symptoms of injury, with intense chlorotic spots 



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GIRALDELI, A.L., et al. 

on the leaves. The herbicide sulfentrazone caused symptoms of sugarcane injury up to 45 DAP, with a 
reduction to 20% in this evaluation, and to 0% from 60 DAP. For diclosulam, injuries were verified up to 90 
DAP, with the highest value at 75 DAP (58.8%). It was observed that the herbicide caused the growth and 
development of sugarcane plants to stop, which also occurred with the application of imazapic. Already 
imazapyr caused severe injuries since the 30 DAP. For post-planting herbicides (halosulfuron, 
ethoxysulfuron, MSMA, and 2,4-D) no symptoms of injury were observed in sugarcane plants in any of the 
evaluations performed (Table 3). 
 
Table 3. Crop injury in pre-sprouted seedlings, cultivar IACSP95-5000, at 30, 45, 60, 75, and 90 DAP. 
Piracicaba, SP, Brazil, 2017/18. 

Treatments Rates¹ Time² 
Crop injury (%) at DAP 

30 45 60 75 90 

control with weeding - - 0.0 0.0 0.0 0.0 0.0 
control without weeding - - 0.0 0.0 0.0 0.0 0.0 
sulfentrazone 800 PRE 37.5 20.0 0.0 0.0 0.0 
diclosulam 193.17 PRE 33.8 46.3 51.3 58.8 48.8 
imazapic 133 PRE 37.5 48.8 57.5 57.5 50.0 
imazapyr 500 PRE 73.8 88.8 92.5 96.0 95.5 
halosulfuron 112.5 POST - 0.0 0.0 0.0 0.0 
ethoxysulfuron 135 POST - 0.0 0.0 0.0 0.0 
MSMA 1,975 POST - 0.0 0.0 0.0 0.0 
2,4-D 1,340 POST - 0.0 0.0 0.0 0.0 

DAP: days after planting; ¹ Rates at g a.i. ha-1, and at g a.e. ha-1 for 2,4-D and imazapyr; ² Herbicide application time: PRE-planting 
(one day before planting) and POST-planting (30 DAP). 

 
Regarding weed control, pre-planting herbicides were generally the ones with the best results. Up to 

45 DAP, all pre-planting herbicides provided “good” control (71 - 80%). After this period only imazapyr 
provided control above 70%, which resulted in a lower dry mass value at 90 DAP (41.88 g). All herbicides 
reduced the percentage of control throughout the evaluations and the dry mass at 90 DAP. From 60 DAP, 
there was a reduction in control percentages for pre-planting herbicides. For the species C. rotundus it was 
verified that the herbicides imazapic, imazapyr, and diclosulam acted as preventing the emergence of the 
species and possibly the germination of the tubers. For sulfentrazone, it is observed that the weeds emerge 
with the herbicide symptoms, which evolve until the plant dies. The symptoms found were chlorotic spots 
on leaves with evolution to necrosis and consequent death. Post-planting herbicide control was not feasible 
as it did not result in efficient weed controls. The maximum control was obtained for halosulfuron and 
ethoxysulfuron at 90 DAP, with 23.8 (114.4 g) and 25% (112.7 g), respectively. All treatments reduced the 
dry mass in relation to the control without weeding, however, they were not equal to the control with 
weeding (Table 4). 
 
 
 
 
 
 
 
 
 
 
 
 
 



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Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system 

Table 4. Control and dry mass of C. rotundus, and other weeds, in pre-sprouted seedlings, cultivar IACSP95-
5000, at 15, 30, 45, 60, 75 and 90 DAP. Piracicaba, SP, Brazil, 2017/18. 

Treatments Rates¹ Time² 
Control (%) at DAP 

Dry mass (g) 
15 30 45 60 75 90 

control with weeding - - 100.0 100.0 100.0 100.0 100.0 100.0 0.0a 
control without weeding - - 0.0 0.0 0.0 0.0 0.0 0.0 219.0f 
sulfentrazone 800 PRE 91.7 90.0 71.3 55.0 41.3 31.3 79.7c 
diclosulam 193.17 PRE 82.7 92.5 80.0 71.3 56.3 25.0 102.9d 
imazapic 133 PRE 80.0 87.5 73.8 62.5 57.5 35.0 50.2b 
imazapyr 500 PRE 83.3 87.0 83.8 82.5 73.8 57.5 41.9b 
halosulfuron 112.5 POST - - 0.0 3.3 11.3 23.8 114.4d 
ethoxysulfuron 135 POST - - 0.0 3.8 17.5 25.0 112.7d 
MSMA 1,975 POST - - 0.0 0.0 1.3 13.8 188.9e 
2,4-D 1,340 POST - - 0.0 10.0 8.8 20.0 148.4e 

  Mean 105.8 
  CV (%) 9.0 
  F * 

DAP: days after planting; ¹ Rates at g a.i. ha-1, and at g a.e. ha-1 for 2,4-D and imazapyr; ² Herbicide application time: PRE-planting 
(one day before planting) and POST-planting (30 DAP).* Means followed by the same letter in the column do not differ by the 
Scott-Knott test (p < 0.05). 

 
The highest sugarcane heights were obtained for treatments without weeding and post-planting 

herbicide application, probably due to the greater competition established in these plots, resulting from the 
low control provided, causing the search for luminosity. Sulfentrazone resulted in height equal to control 
(with weeding). For diclosulam, imazapic and imazapyr were the lowest heights. Concerning the stem 
diameter (60 DAP), the lowest values were verified for the herbicides diclosulam, imazapic and imazapyr 
compared to the control with weeding and without weeding. In this evaluation, the number of tillers was 
lower for all treatments compared to control (with weeding). Among the pre-planting herbicides, the largest 
number of tillers was in sulfentrazone treatments. The analysis of variance was significant at 90 DAP for the 
variables: height, diameter, and the number of tillers. The lowest heights and diameters were observed for 
diclosulam, imazapic, and imazapyr application, compared to weeding control, however, sulfentrazone did 
not differ from imazapic for the variable height. All herbicides and control (without weeding) reduced the 
number of tillers when compared to control (with weeding) (Table 5). 
 
Table 5. Height, diameter, and tillers number, of pre-sprouted seedlings, cultivar IACSP95-5000, at 60 and 
90 DAP. Piracicaba, SP, Brazil, 2017/18. 

Treatments Rates¹ Time² 
Height (cm) Diameter (mm) Tillers 
60 90 60 90 60 90 

control with weeding - - 34.1b 54.0a 18.0a 21.8a 10.7a 14.4a 
control without weeding - - 55.1a 72.0a 18.2a 23.3a 2.0b 1.7b 
sulfentrazone 800 PRE 31.7b 52.9a 14.4a 20.0a 5.0b 4.4b 
diclosulam 193.17 PRE 14.5c 23.8b 5.4b 11.7b 0.1c 0.4c 
imazapic 133 PRE 14.2c 33.3b 6.0b 14.1b 0.2c 0.3c 
imazapyr 500 PRE 4.2d 2.7c 3.8b 2.7c 0.0c 0.0c 
halosulfuron 112.5 POST 52.1a 63.1a 17.4a 22.5a 2.2b 2.4b 
ethoxysulfuron 135 POST 52.7a 55.9a 18.0a 21.6a 3.0b 2.4b 
MSMA 1,975 POST 53.2a 61.0a 17.7a 20.9a 2.6b 2.2b 
2,4-D 1,340 POST 50.8a 57.9a 16.0a 21.0a 2.5b 2.0b 

Mean 36.2 47.7 13.5 18.0 2.8 3.0 
CV (%) 14.1 17.0 15.6 12.7 17.9 15.8 

F * * * * * * 
DAP: days after planting; ² Herbicide application time: PRE-planting (one day before planting) and POST-planting (30 DAP).* Means 
followed by the same letter in the column do not differ by the Scott-Knott test (p < 0.05). 



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GIRALDELI, A.L., et al. 

For the evaluation at 120 DAP, the analysis of variance indicated statistical difference for all variables. 
The lowest heights were observed for the application of diclosulam (37.1 cm), imazapic (45.3 cm), and 
imazapyr (10.75 cm), and for ethoxysulfuron which differed from control (with weeding). For diameter, the  
lowest values were also obtained for diclosulam, imazapic, and imazapyr (13.0, 16.3, and 4.8 mm). All 
treatments reduced the number of tillers when compared to control (with weeding). At 240 DAP, the analysis 
of variance showed a reduction in height for all treatments compared to weeding control, except for the 
herbicide sulfentrazone, which was the same. The diameter was lower only for imazapyr application, as there 
were no more plants to be evaluated due to plant death. All treatments were lower than control (with 
weeding) in the number of tillers and weight of ten stems, except sulfentrazone herbicide for weight variable 
(Table 6). 
 
Table 6. Height, diameter, and tillers number, at 120 and 240 DAP, and yield of pre-sprouted seedlings, 
cultivar IACSP95-5000. Piracicaba, SP, Brazil, 2017/18. 

Treatments Rates¹ Time² 
Height (cm) Diameter (mm) Tillers Yield 

120 240 120 240 120 240 (t ha-1) 

control with weeding - - 102.4a 143.0a 28.6a 33.3a 12.8a 80.0a 66.2a 
control without weeding - - 92.7a 97.3b 26.6a 31.6a 2.5c 23.5b 11.0c 
sulfentrazone 800 PRE 84.7a 111.5b 26.2a 32.2a 5.9b 36.0b 27.1b 
diclosulam 193.17 PRE 37.1b 44.9c 13.0b 23.3b 0.7d 16.3c 2.9c 
imazapic 133 PRE 45.3b 52.2c 16.3b 25.1b 2.8c 22.3b 6.4c 
imazapyr 500 PRE 10.8c 0.0d 4.8c 0.0c 0.3d 0.0c 0.0c 
halosulfuron 112.5 POST 89.7a 104.5b 25.8a 32.3a 4.9b 30.0b 18.4b 
ethoxysulfuron 135 POST 74.7a 89.8b 23.9a 31.1a 5.3b 33.0b 16.8b 
MSMA 1,975 POST 87.2a 99.6b 25.1a 31.5a 5.3b 35.0b 19.8b 
2,4-D 1,340 POST 91.2a 95.1b 24.7a 33.4a 4.6b 34.0b 18.9b 

Mean 71.5 83.8 21.4 27.4 4.5 31.0 18.8 
CV (%) 14.2 17.9 12.4 15.4 35.9 38.9 45.0 

F * * * * * * * 
DAP: days after planting; ² Herbicide application time: PRE-planting (one day before planting) and POST-planting (30 DAP).* Means 
followed by the same letter in the column do not differ by the Scott-Knott test (p < 0.05). 

 
4. Discussion 

The lower number of tillers combined with the smaller weight of ten stems is reflected at yield. 
However, it is noteworthy that the low yields are also due to the experiment time (240 days) because the 
aim of the study is to simulate a seedling vivarium, in which the recommendation is 8 to 10 months (Amaral 
and Azania 2017). For the application of sulfentrazone, halosulfuron, ethoxysulfuron, MSMA, and 2,4-D, the 
yield was lower than that observed in the weeding control, but all were superior to the control (without 
weeding). These results suggest that the reduction in yield is due to insufficient weed control, not due to 
lack of selectivity, which is also indicated by the absence of severe sugarcane injury symptoms. While for the 
application of diclosulam, imazapic, and imazapyr there was lower yield even than the control (without 
weeding), suggesting that these herbicides were not selective for sugarcane (Table 6). The high symptoms 
of injury in PSS in PRE applications were evidenced, possibly due to the time elapsed between herbicide 
application and planting, which was one day. Diclosulam is recommended for weed pre-emergence, in 
conventional planting, after planting or harvest of sugarcane, at a rate of 105.8 to 194 g a.i. ha-1, for the 
control mainly of U. plantaginea, D. horizontalis, I. triloba L. and C. rotundus (Rodrigues and Almeida 2018). 
However, there is no recommendation for planting with PSS. 

It is noteworthy that the three herbicides applied in PRE (diclosulam, imazapic, and imazapyr), that 
were potentially non-selective, are of the same mechanism of action (ALS inhibitors), which suggests care in 
the application of herbicides of this mechanism one day before the planting of PSSs.  The selectivity of 
herbicides may be different in the PSS system than that observed in the conventional system, the PSSs 
already have a root system, and when placed in contact with the soil the root system is in the region treated 
with the herbicide, which is the main route of absorption of herbicides applied at PRE, and there may be an 



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Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system 

absence of selectivity by positioning. Possibly higher rates of absorption and translocation of herbicides (Dias 
et al. 2017; Silva et al. 2018). 

Planting PSS from CTC 14, CTC 7 and RB966928 cultivars, shortly after diclosulam application (200 g 
a.i. ha-1), resulted in injury of 8.3% (14 DAA), 21.9% (28 DAA), 34.6% (42 DAA) e 26.3% (63 DAA). At 63 DAA, 
the plants had not yet recovered from injuries, with symptoms of 33.5% (CTC 14), 21% (CTC 7) and 24.3% 
(RB966928). Consequently, there was a reduction in plant height in relation to control (without weeding) 
and a lower number of tillers in cultivars CTC 14 and RB966928 (Dias et al., 2017). Reduction in height and 
number of tillers was also observed in the present study for the cultivar IACSP95-5000, with higher 
symptoms of injury: 46.25% (15 DAP), 51.25% (30 DAP), 58.75 % (45 DAP) and 48.75% (60 DAP). 

PRE application of diclosulam at rates 126 or 168 g a.i. ha-1 resulted in excellent (over 95%) weed 
control for U. plantaginea, U. decumbens, P. maximum, and D. horizontalis (Takano et al. 2017). For C. 
rotundus, the use of diclosulam (200 g a.i. ha-1) reached control scores of 91.5% (45 DAA), 96.5% (60 DAA) 
and 93.5% (90 DAA), reducing the number of germinated, dormant and dead tubers in relation to control 
(without application) (Martins et al. 2009). In the present study, diclosulam provided a reduction in the 
emergence of C. rotundus, P. maximum and D. ciliaris species reaching overall control of 82.67% (15 DAP), 
92.5% (30 DAP), 80% (45 DAP ), reducing from 60 DAP, mainly due to the presence of species such as A. 
tenella and P. oleraceae. 

The use of imazapic (140 g a.i. ha-1) in pre-emergence of cultivar SP81-3250 (Plene® system) caused 
severe injury, which reflected in high harvest losses. The herbicide also reduced plant height by 33.6 cm, the 
number of tillers by 13, the leaf + stem dry mass by 40.1 g and the root dry mass by 96.9 g, all compared to 
the control (without application), 110 days after budding (Bertolino and Alves 2014). In the present work, 
the use of imazapic (133 g a.i. ha-1) in PSS reduced plant height by 90.8 cm, the number of tillers by 57.57, 
the weight of ten stalks by 5.05 g and the yield on 59.81 t ha-1, all compared to control (with weeding) at 240 
DAP. 

In sugarcane, imazapic is recommended at a rate of 245 g a.i. ha-1, at 30 to 45 days before planting, 
at pre or post-emergence of weeds. In new cycles, after the first harvest, until 122,5 g a.i. ha-1, with the 
application before crop emergence. This herbicide acts in the control of several weeds that were present in 
the study area as A. tenella, E. indica, P. oleraceae, P. maximum, and U. plantaginea. Thus, as in C. rotundus 
control at 133 g a.i. ha-1 (medium soil) and 145 g a.i. ha-1 (clay soil) (Rodrigues and Almeida 2018). For 
imazapic, general weed control was considered “very good” (81 - 90%) until 30 DAP, “good” (71 - 80%) at 45 
DAP, and “sufficient” (61 - 70%) at 60 DAP. For C. rotundus, the herbicide probably acted by preventing plant 
germination or emergence. The effective control of imazapic over this weed has been proven by several 
authors. Simoni et al. (2006) observed a reduction in the dry mass of the shoot and basal bulbs at rate 147 g 
a.i. ha-1. 

For sulfentrazone, 37.5% (30 DAP) and 20% (45 DAP) injury symptoms were observed, characterized 
as red spots on the leaves, which were no longer seen from 60 DAP. Martins et al. (2009) found red elliptic 
stains on the leaf. The injury was also found by Sabbag et al. (2017) at PSS of RB867515, RB855156, 
RB966928, and RB975201, for sulfentrazone (700 g a.i. ha-1), at 3 and 10 DAP. The rate of 800 g a.i. ha-1 of 
sulfentrazone, applied on the same day of planting provided high injury, and the different cultivars were 
tolerant up to 400 g a.i. ha-1 (Silva et al. 2019). 

The selectivity of sulfentrazone (800 g ai ha-1) in PSS was observed by Perez (2017), who found injury 
of 21.3% (15 DAA), 20% (30 DAA), 16.3% (60 DAA), 11.3% (90 DAA) and 5% (120 DAA) when the herbicide 
was applied one day before planting of CTC 11 cultivar. However, it was considered selective because it did 
not reduce plant height, number of tillers, and yield. In the cultivar of the present study, no injuries were 
observed from 60 DAP. The decrease in yield and the number of tillers can be attributed to the level of weed 
control, which was "good" (71-80%) only until 45 DAP, with new weed germination and emergence, which 
started to compete with the crop and consequently reducing the yield. 

In the present study, the herbicide was effective up to 45 DAP, from 60 DAP the control reduced to 
90 DAP, probably due to the high seed bank infestation, mainly of monocotyledons such as C. rotundus, D. 
ciliaris, P. maximum and C. echinatus, besides eudicotyledons A. tenella and P. oleraceae. The efficacy of 
sulfentrazone is proven for several weeds, such as E. heterophylla, I. nil (L.) Roth, I. hederifolia, I. quamoclit, 
I. triloba and M. aegyptia (L.) Urb. (Azania et al. 2009), C. rotundus (Simoni et al. 2006; Almubarak and 



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9 

GIRALDELI, A.L., et al. 

Srivastava 2015). Amstalden et al. (2008) analyzed the use of sulfentrazone (800 g a.i. ha-1) in 100 sugarcane 
crops in the control of C. rotundus, in which control over 80% was observed in 88 crops. In the remaining 12, 
where the control was less than 80%, the results are explained by the high infestations (some with more 
than 500 plants m-2) or using lower rates than recommended. 

The efficacy of sulfentrazone up to 45 DAP can also be explained by the cumulative rainfall of 338.6 
mm until this assessment. Absorption of this herbicide is performed mainly via the root. High temperatures 
and rainfall may have contributed to the herbicide being leached into deeper soil layers, where most of the 
weed seed bank is not concentrated, allowing a new emergence flow before the crop could close the rows. 
As highlighted by Carbonari et al. (2016), this herbicide is recommended especially in the dry season, 20 mm 
of precipitation is already enough to extract about 80% of the herbicide applied under the straw and 
sugarcane residues. Monquero et al. (2010) observed that the effect of leaching increased as rainfall 
increased. Regarding the persistence of sulfentrazone (800 g a.i. ha-1), they found that up to 45 DAA the 
accumulated precipitation was 174 mm, which contributes to an 80% control of the bioindicator.  

For imazapyr, it was verified that the application one day before planting leads to the death of the 
IACSP95-5000 cultivar. This result was already expected since the herbicide is recommended in pre or post-
emergence of weeds and should wait at least 60 days for planting (Rodrigues and Almeida 2018). Regarding 
weed control, imazapyr was the one that kept control as “sufficient” for the longest time (61 - 70%), with 
reduction only at 90 DAP (57.5%). Imazapyr has a broad control spectrum, encompassing the main weeds 
present in the study area: C. rotundus, A. tenella, B. subalternans, U. plantaginea, C. benghalensis, E. indica, 
and P. maximum. Dias et al. (2005) observed 100% control for D. ciliaris at 21 DAA of imazapyr (125 g a.e. 
ha-1). 

No injury was observed when post-planting herbicides were used. Chand et al. (2014) found no injury 
to halosulfuron (up to 150 g a.i. ha-1) in sugarcane for application at 45 DAP. The high weed infestation in 
post-planting treatments made the plants compete for light. This fact can be observed by the higher heights 
in these treatments and in the control (without weeding) at 60 DAP, besides the smaller amount of tillers. 
Being a C4 metabolism plant, sugar cane needs a lot of light; reduced irradiation conditions lead to longer, 
thin stalks, and lower tillering plants (Rodrigues 1995). Thus, sugarcane tillering will be lower under low light 
intensity conditions (Jadoski et al. 2010). 

Chand et al. (2014) found control of elevated C. rotundus, above 90% at 60 DAA, when halosulfuron 
(45 DAP) was used at 60, 67.5, 75, and 150 g a.i. ha-1. In contrast, mechanical weeding and continuous 
chemical management with atrazine (2,000 g a.i. ha-1) at pre-emergence, and 2,4-D (1,000 g a.e. ha-1, at 45 
DAP) increased the number of plants m-², since they were not effective in controlling this species. However, 
atrazine and 2,4-D were effective in controlling other monocotyledons and eudicotyledons, while 
halosulfuron did not provide large reductions in dry mass of these species. In the present study, it was found 
that halosulfuron alone was not enough to keep sugarcane free from weeds, mainly grass species, which 
consequently reduced crop yield.  
 
5. Conclusions 

Sugarcane weed management through chemical control is an important tool that helps maintain 
yield. However, it should be combined with other methods, prioritizing integrated weed management, 
especially when species are difficult to control. Pre-planting herbicides provided the best weed controls, but 
diclosulam, imazapic, and imazapyr caused a severe injury in PSS. The sulfentrazone gave the second highest 
yield, after control (with weeding). Nevertheless, sulfentrazone was considered the most satisfactory in this 
study. Post-planting herbicides did not cause injury to the sugarcane but alone were not effective in 
controlling weeds, which caused a reduction in yield. The results obtained here are noteworthy since there 
are few studies on herbicide management at the field in the sugarcane PSS system. 
 
Authors' Contributions: GIRALDELI, A.L.: conception and design, acquisition of data, analysis and interpretation of data, drafting the article, and 
critical review of important intellectual content; SILVA, A.F.M.: conception and design, acquisition of dat a, analysis and interpretation of data, 
drafting the article, and critical review of important intellectual content; BACCIN, L.C.: conception and design, acquisition of data, analysis and 
interpretation of data, drafting the article, and critical review of important intellectual content; ARAÚJO, L.S.: conception and design, acquisition 
of data, analysis and interpretation of data, drafting the article, and critical review of important intellectual content; SILVA, G.S.: conception and 
design, acquisition of data, analysis and interpretation of data, drafting the article, and critical review of important intellectual content; 



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10 

Chemical management of Cyperus rotundus L. and other weeds at sugarcane in PSS system 

PAGENOTTO, A.C.V.: conception and design, acquisition of data, analysis and interpretation of data, drafting the article, and critical review of 
important intellectual content; VICTORIA FILHO, R.: conception and design, acquisition of data, analysis and interpretation of data, drafting the 
article, and critical review of important intellectual content. All authors have read and approved the final version of the manuscript. 
 
Conflicts of Interest: The authors declare no conflicts of interest. 
 
Ethics Approval: Not applicable. 
 
Acknowledgments: The authors would like to thank the funding for the realization of this study provided by the Brazilian agency CAPES 
(Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil), Finance Code 001. 
 

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Received: 31 November 2019 | Accepted: 25 August 2020 | Published: 13 October 2021 

 

 

  

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